"""commom"""
import keras.backend
from .dynamic import meshgrid


def bbox_transform_inv(boxes, deltas, mean=None, std=None):
    """ Applies deltas (usually regression results) to boxes (usually 
    anchors).

    Before applying the deltas to the boxes, the normalization that was 
    previously applied (in the generator) has to be removed.
    The mean and std are the mean and std as applied in the generator. 
    They are unnormalized in this function and then applied to the boxes.

    Parameters
    ----------
    boxes : np.array 
        Shape (B, N, 4), where B is the batch size, N the number of boxes 
        and 4 values for (x1, y1, x2, y2).
    deltas: np.array 
        Same shape as boxes. These deltas (d_x1, d_y1, d_x2, d_y2) are a 
        factor of the width/height.
    mean : float
        The mean value used when computing deltas (defaults to [0, 0, 0, 0]).
    std : float
        The standard deviation used when computing deltas (defaults to [0.2, 
        0.2, 0.2, 0.2]).

    Returns
        A np.array of the same shape as boxes, but with deltas applied to 
        each box.
        The mean and std are used during training to normalize the regression 
        values (networks love normalization).
    """
    if mean is None:
        mean = [0, 0, 0, 0]
    if std is None:
        std = [0.2, 0.2, 0.2, 0.2]

    width = boxes[:, :, 2] - boxes[:, :, 0]
    height = boxes[:, :, 3] - boxes[:, :, 1]

    x1 = boxes[:, :, 0] + (deltas[:, :, 0] * std[0] + mean[0]) * width
    y1 = boxes[:, :, 1] + (deltas[:, :, 1] * std[1] + mean[1]) * height
    x2 = boxes[:, :, 2] + (deltas[:, :, 2] * std[2] + mean[2]) * width
    y2 = boxes[:, :, 3] + (deltas[:, :, 3] * std[3] + mean[3]) * height

    pred_boxes = keras.backend.stack([x1, y1, x2, y2], axis=2)

    return pred_boxes


def shift(shape, stride, anchors):
    """ Produce shifted anchors based on shape of the map and stride size.

    Args
        shape  : Shape to shift the anchors over.
        stride : Stride to shift the anchors with over the shape.
        anchors: The anchors to apply at each location.
    """
    shift_x = (keras.backend.arange(0, shape[1], dtype=keras.backend.floatx(
    )) + keras.backend.constant(0.5, dtype=keras.backend.floatx())) * stride
    shift_y = (keras.backend.arange(0, shape[0], dtype=keras.backend.floatx(
    )) + keras.backend.constant(0.5, dtype=keras.backend.floatx())) * stride

    shift_x, shift_y = meshgrid(shift_x, shift_y)
    shift_x = keras.backend.reshape(shift_x, [-1])
    shift_y = keras.backend.reshape(shift_y, [-1])

    shifts = keras.backend.stack([
        shift_x,
        shift_y,
        shift_x,
        shift_y
    ], axis=0)

    shifts = keras.backend.transpose(shifts)
    number_of_anchors = keras.backend.shape(anchors)[0]

    # number of base points = feat_h * feat_w
    k = keras.backend.shape(shifts)[0]

    shifted_anchors = keras.backend.reshape(
        anchors, [
            1, number_of_anchors, 4]) + keras.backend.cast(
        keras.backend.reshape(
            shifts, [
                k, 1, 4]), keras.backend.floatx())
    shifted_anchors = keras.backend.reshape(
        shifted_anchors, [k * number_of_anchors, 4])

    return shifted_anchors
